FR2597258A1 - Programmable multi-circuit presence simulator - Google Patents

Abstract

The invention relates to a presence simulator device for preventing burglary when buildings are unoccupied. It consists of invertor switches IV and make/break switches I, the opening or closing F of which is controlled by a programmer P which is turned on through a make/break switch H. When IV is in position 2, the presence simulator apparatuses A (lamps, radios etc.) plugged into the electrical circuits C of the building are normally supplied by the current source S. When H is in the closed position and IV in position 1, the current supply to the circuits C is controlled by the opening or closing of the make/break switches I. The state of the make/break switches I is controlled by the programmer. Thus the apparatuses A undergo successive off and on cycles at planned times and for periods defined by the programme in P. It therefore suffices for the occupant leaving the building to close H and set IV in position 1 so that a presence is simulated in the building.

Description

 The present invention relates to devices for automatically simulating a presence in a building (eg factory, warehouse, apartment, house) whose occupants are absent, this in order to deter intruders (for example burglars) from to enter this building.

 The operation, visible from the outside of the building, of various devices such as a lit lamp, a radio in operation or a television broadcasting a program are all signs suggesting that the occupant of a building is present. In order to simulate a presence, it suffices, for example, to switch on a lamp intermittently in a room or to connect a television or radio set for shorter or shorter periods of time, in the absence of a light. usual occupant of the building. We can also provide more sophisticated devices such as electric motors, which associated with a mechanical device, open or close shutters or curtains.

 Currently, to simulate a presence according to the principle described above, we can equip the various devices (lamps, radio, motors, etc.) of programmable watchmakers whose function is to put them under (or off) voltage at times (and days). ) accurate programmed in advance.

 The use of a single clock on which are connected all devices to simulate a presence, however, two problems: the first concerns the maximum amperage expected for the clock that can limit the number of devices to use, the second pose a problem of credibility. All devices operating or stopping simultaneously is not a perfect simulation of human presence, this situation is very difficult to achieve in everyday life.

 The use of a programmable clock for each device, besides this solution necessitates the possession of several clocks, poses a synchronization problem for each of these clocks if one wishes, so that they remain credible. Moreover, each time the occupant returns to the building, he must remove each clock or cancel their function in order to be able to use normally (without switching on or off by the clock) each of the devices used for the presence simulation. .

 The invention described in this patent aims to simulate a human presence in an unoccupied building, by operating or stopping the operation of various devices such as for example lamps, radio, television, tape recorders.

 The putting into operation or stopping of these devices, brought to the knowledge of a person located outside the building (or in an adjoining room) inclines this person to think that the building is occupied. The invention makes it possible to use several devices, by programming in advance and independently of each other, time cycles of stopping and putting into operation of each of these devices in a scheduled chronological order.

 The start-up (or shutdown) is done by an electrical power-up or / and a power cut-off. The shutdown or / and power cut is ensured, for each device intended to simulate a presence, by opening or / and closing switches or other devices intended to cut a voltage or put a voltage. For example, the switches can be of the mechanical type, electrotechnical (killed for example) or electronic. The opening or closing of the aforementioned switches is provided by a programmer which can be of the mechanical type (for example called cams) or electronic type, including a computer. The start of the programmer ensures the execution of a opening and closing cycle of each and / or several switches according to time sequences provided during the development of the programmer program. The programmer can be switched on manually by the occupant when he leaves the building or automatically, for example using a programmable clock. It is also possible to provide on the various electrical circuits concerned switches with several positions (for example of the back-and-forth type or any other multi-position switch). The placing on a particular position of these switches will make it possible to use the simulator devices. presence in a normal operating mode, ie without the programmer eb its ancillary accessories (switches for example) have any influence on their mode and cycle of operation. It will also be possible to provide a control device (lamp for example) making it possible to ensure that the presence simulation programmer is running. It is also possible to envisage the use of a single multi-channel switch (of the mechanical or electronic type, for example a relay) for manually switching (or automatically, for example using a programmable clock) a position where the devices operate in the so-called "presence simulator" mode at a position called "normal mode" allowing the occupant to use these devices without being disturbed by the presence simulator device.

 It can be expected that the devices intended to simulate a presence will all be connected for example to a mobile box having power outlets whose supply (or non-foodaiton) will be provided by the programmer located in the same box, the whole being supplied with power by plugging on the current source of the building.

 It can also be expected that the devices will be connected to the usual electrical circuits of a building (eg socket outlets or sockets) and that it is the power supply of these circuits that will be controlled, when it will be implemented. function, by the programmer. The programmer and its ancillary accessories (for example switches) can then be grouped for example in the same box located near a switchboard.

 It is also possible to provide for possible program changes, for example by using, in the case of a cam mirror, adjustable cams and / or interchangeable cut cams and / or cams with cleats.

 It is also possible to provide for automatic shutdown at the end of the programmer's cycle which will leave, for example, switches in a position such that the appliances intended to emit a presence will be powered according to the normal mode.

 It will also be possible to use several programmers, grouped or not, synchronized or not, placed in several areas of the building when the use of one will not be possible or difficult to implement.

 Safety fuses may also be provided on certain circuits. The use of this device is normally provided by a main source. It can also be planned to connect it to a secondary power supply (for example a generator) if this is deemed useful.

The invention will be described below in more detail with reference to particular embodiments (cited purely as an example) and the accompanying drawings, which are provided for purely illustrative and non-limiting purposes and in which :
Fig. 1 shows a general pattern of operation.
FIG. 2 shows a particular embodiment of the invention
Table I describes a simulation cycle related to the realization
described in fig. 2.

Fig.3 describes the cutting of the cams of the programmer P of the sheave
described in Figure 2, cutting carried out according to
cycle and scenario described in Table I.

FIG. 4 describes another particular embodiment according to the invention.
vention.

FIG. 5 describes another embodiment of the embodiment according to FIG.
vention.

 Referring now to FIG. 1, Al, A2, A3 and A4 are four devices (this number is not limiting but taken as an exception) which put into operation (or at rest) simulates a presence. (eg lamp on, radio running, etc.). The power supply wire of these devices is connected to the terminal F of switches I1 I2 I3 14 associated therewith. The same switch may also be associated with several devices and the same device may have a power supply connected to several switches.

The terminal C of the switches I @ 12 13 14 is connected to a source of current S.

When the switches I1 I2 I3 I4 are in the open position (0 in FIG. 1), the devices A1, A2, A3, A4 are not energized and therefore do not work. When I1 12 13 14 are in the closed position (F in FIG. 1), the devices A1, A2, A3, A4 operate. The programmer P, puts in the closed (F) or open (O) each of the switches I1 12 I3 IJ according to a cycle determined in advance. The particular cycle of opening and closing sequence constituting the program of the programmer. The programmer is turned on by means of an IP switch which controls its power-up. IP-can be a manual switch that the occupant puts in the closed position (F) when leaving the building in order to simulate a presence during his absence. IP can also be a programmable switch (for example a programmable timed circuit breaker) which automatically activates the presence simulator at predicted times and dates, and avoids the occupant thinking about starting the simulator. presence when leaving the building.

 The development of the program of the programmer may provide simple correlations between opening one switch and closing another if these switches are associated devices located in two neighboring rooms for example.

 Figure 2 shows a practical example of embodiment according to the invention.

In this example S is a current source which supplies the programmer P, which is, in this example, a mechanical cam programmer. When P is turned on, the cams, fixed on the shaft of its engine rotate with this axis. During their rotation and depending for example on their cutting, if
P is a camshaft programmer, the cams open and close the switches I1 I2 I3 I4 a number of times and for a predicted time during cutting. The point C of the switches I1 I2 I3 I4 is connected for example to the phase PH of the current source S. When I1 12 I3 14 are in the closed position, the PH phase is thus brought to PR1 outlets
PR2, PR3 and PR4. In this case, the orogrammer P,] the associated interriipers and power outlets are contained in a mobile and portable box B, the PR1, PR2, PR3 and PR4 sockets being located on the periphery of the box and accessible from outside the cabinet. The power supply of the outlets PR1, PR2, PR3 and PR4 is thus controlled by the programmer according to the program provided during the cutting of the cams. Electronics
Al, A2, A3, A4 (intended to simulate a presence) are in this example located in four rooms Pi, P2, P3 and P4 of the building. Their power outlets are respectively connected to the PRI, PR2, PR3 and PR4 jacks using wires of adequate length. In this example the box B is placed in a central part with respect to the nieces @ 1, P2 , P3 and P4 so as to minimize the lengths of power wire. In this way the apparatuses AI, A2, A3 and A4 are alternately turned on or off according to the progress of the program provided in the programmer P.

 Table I describes a nessible sequence of shutdowns and start-up of the Al, A2, A3 and A4 devices for a planned scenario of comings and goings in rooms PI, P2, P3 and P4 of the building to determined hours in advance.

 FIG. 3 describes the cutting of the cams CA1, CA2, CA3 and CA4 which control the switches I1 12 I3 and 14. The cutting of each of them corresponds to the scenario provided for in Table I. In this example, each of the cams will take a complete turn. in I hour. The origin (OR in Figure 3) is the starting point, it is also where the point of contact with the switch is located. An arrow indicates the direction of rotation of the cams. When this point of contact corresponds to a hollow of the cam, the switch is in the closed position (see Fig. 3). The position of this point at times t = 15 min, 30 min, 45 min was shown in Figure 3 to facilitate understanding.

 FIG. 4 describes a particular embodiment of the invention in which S is the main source of current of the building and T is a distribution board for the electrical circuits C1, C2, C3 of the building.

These circuits can correspond, for example, to the 16-amp electrical outlets of a room or to the IOA circuits intended for lighting. PFI, PF2 etc. are the fuse holders associated with each of circuits C1, C2, etc. In a conventional domestic installation, the phase wire coming out of the fuse holders goes directly to the corresponding circuit. In the embodiment of the invention, this phase wire (it could also be another feed wire) is connected to the midpoint M of a switch IV (IVI, IV2, IV3 etc.) of the type-va and comes to two contact positions (point I and 2, see FIG.

 Point 2 is directly connected to circuits C1, C2, C3 etc. When the switch IV is in position 2, the contact exists between the point M and the point 2 and the circuits Ci, C2, C3 and C4 are normally under tension.

This is the classic operation of a home installation.

The point I of the switches IVi, IV2, 1V3 is connected to the point 2 of the relay switches R1, R2, R3, which when energized are in poaition closed. The point I of these relay switches R1, R2, R3 is connected to point 2 of the switches I1, I2, T3, the opening or shutter of which is controlled by the programmer P. The point I of the switches
I1, I2 and 13 is connected directly to circuits C1, C2, C3. The power supply of the programmer P and the relays Ri, R2, R3 is controlled by the position of a switch H whose closure or opening is either manual or automatic. In the latter case H may be a self clock mastic for example.

The mode of use and operation is then the following. When the occupant is in the house the switches IV1, IV2 and IV3 are in position 2. In this case the circuits CI, C2, C3 are supplied normally without the programmer and its associated switches disturbing them.
When the occupant leaves the building, he plugs the devices intended to simulate a presence on the circuits Ci, C2 and C3 and then switches the switches IVI, IV2 and IV3 in position I as well as the switch H if the latter does not. is not controlled automatically.It also sets the programmer so that the program starts on the prevailing sequence. Thus the circuits ~ CI, C2, C3 are fed according to the program P from the moment of closure of H, since the latter allows the power supply of the programmer P and relay switches R1, R2, R3 which are then in closed position. (see fig 4).

On his return to the building the occupant puts again the switches IVI, IV2, IV3 in position 2, so as to use normally the circuits CI,
C2, C3.

 The programmer set P and associated switches (1v, R, I, H) is contained for example in a box B (distribution box type) placed near a distribution board or even directly integrated therewith.

 Finally, it should be noted that the presence of the relays R is not mandatory, but it nevertheless makes it possible to cut off all power to the circuits C1, C2, C3 when the switches IV are in position 1, as long as the programmer P is not powered. Indeed, if the programmer P is for example of the cam type, during its last cycle it may have been stopped at a sefluence such that one of the cams leaves one of the switches I in the closed position.

When setting I switches IV, a circuit can then be powered without the programmer has started his program. It can follow a loss of credibility of the simulation of presence if this circuit feeds for example a lamp that will remain lit in daylight. To overcome this disadvantage, it is also possible to suppress the relays R, but to use a programmer P which automatically returns to the original position when the voltage is cut off. In this case, it is necessary to connect the reset device upstream of the switch H.

 It can also be provided that the various switches IVI, IV2, TV3, etc. can be placed in position I or 2 automatically, for example using the switch H, which can be, in this case, a two-way switch. positions (manual or automatic).

 FIG. 5 shows a variant of the embodiment described in FIG. 4 where the switches 11, I 2, I 3, etc. are necessarily in this case electromagnetic relays R 1, R 2, R 3, etc. In this example, the programmer is a computer equipped with a parallel output interface (ISP) (for example 8 bits). By program we can set to O or I each of the bits of ISP, which is reflected on the corresponding pads 1, 2,3, etc. by the presence (or absence) of a permanent TTL voltage of 0-5 Volts. These TTL voltages are converted by a power card (CP) which allows for example to transform these voltages into voltage 0-24Volts so as to supplying, with sufficient amperage, the relays Ri, R2, R3, etc. and thereby controlling their opening or closing, and thereby supplying power to the circuits Ci, C2, C3.

By using the computer as a programmer, the simulation possibilities are immense. We can indeed provide very general programs taking into account for example parameters such as the time of sunrise and sunset, the day of the week, the dates of holidays, etc., etc. When the occupant leaves the building, he
in the computer then simply enter the date and time of exit / and start the program. Everything can then proceed automatically as in the previous examples.

It follows from the description above that the invention provides a device for simulating a presence in an unoccupied building. It goes without saying that the invention is not limited to the details of the embodiments described above and that many modifications can be made to cope with various conditions or special requirements without departing from the scope of the invention. invention as defined in the following claims.

time <SEP> 0 <SEP> to <SEP> 10 <SEP> 10 <SEP> to <SEP> 20 <SEP> mn <SEP> 20 <SEP> to <SEP> 25 <SEP> mn <SEP> 25 <SEP> to <SEP> 40 <SEP> mn <SEP> 40 <SEP> to <SEP> 55 <SEP> mn
<tb> action <SEP> assumed <SEP> the occupant <SEP> is <SEP> it <SEP> passes <SEP> in <SEP> P2 <SEP> it <SEP> passes <SEP> in <SEP> P3 <SEP> it <SEP> passes <SEP> in <SEP> P4 <SEP> it <SEP> passes <SEP> in
<tb> in <SEP> P <SEP> 1 <SEP> P1 <SEP> in <SEP> leaving
<tb> of <SEP> the occupant <SEP> A1 <SEP> is <SEP> on <SEP> A1 <SEP> is <SEP> off <SEP> A2 <SEP> is <SEP> off <SEP> A3 <SEP> is <SEP> off <SEP> A4 <SEP> on
<tb> A2 <SEP> is <SEP> on <SEP> A3 <SEP> is <SEP> on <SEP> A4 <SEP> is <SEP> on
<tb><SEP> position of <SEP> I1 <SEP> closed <SEP> open <SEP> open <SEP> open <SEP> closed
<tb><SEP> position of <SEP> I2 <SEP> open <SEP> closed <SEP> open <SEP> open <SEP> open
<tb><SEP> position of <SEP> I3 <SEP> open <SEP> open <SEP> closed <SEP> open <SEP> open
<tb><SEP> position of <SEP> I4 <SEP> open <SEP> open <SEP> open <SEP> closed <SEP> closed
<Tb>

 TABLE I

Claims (10)

- REVENi) I (: AT-1ONS.  1.- Presence simulator device for unoccupied building, characterized in that it includes electrical circuits on which are connected devices intended to simulate a presence (ordinary household appliances or other), the absence or the presence of electrical voltage on these circuits being controlled by the open or closed position of switches, which position of said switches is controlled by a programmer that executes, according to a specific program, cycles of opening and closing of the various switches.  2.- Presence simulator device according to claim I ca ractérisé by electrical circuits ending in sockets, which are located on (or around) a mobile and portable box including inside the programmer and switches associated, the assembly being electrically powered by one of the current arrivals of the building (see fig 2).  3.- Presence simulator device according to claim I characterized in that it is designed to use the electrical circuits of a building, the programmer controlling the presence or absence of voltage on these circuits, the action of which programmer can be eliminated by means of multi-position switches placed before or after a distribution board, the action of which switches allowing the normal use of the said electrical circuits (see fig 4).  4. Presence simulator device according to claim 3 charac terized by a fixed box containing the programmer and the various switches and associated accessories and externally one or more switches for turning on or off said device.  5.- Presence simulator device according to claims 1, 2, 3 and 4 characterized in that its activation and out of function is automatically controlled by means of electromagnetic or electronic switches and / or programmable clocks.  6.- Presence simulator device according to claims I to 5 characterized in that witnesses (eg lamps) to check if it is in function.  7.- Presence simulator device according to claims I to 6 characterized in that the programmer is a mechanical cam programmer, the cams being adjustable, 3 cut or cleats, the size or adjustment of the cams being performed for a specific cycle opening of the switches (see fig 3).  8.- Presence simulator device according to claims I to 6 characterized in that the programmer is a computer, the opening or closing position of the switches being controlled by the computer state of a parallel output card which can associated with a card adapted to the characteristics of the switches to operate.  9.- Presence simulator device according to claims I to 6 cacacterized in that the programmer is of the electronic type, which may contain for example a microprocessor.  10.- Presence simulator device according to claims I to 9 characterized in that the automatic or manual action of a single switch (eg multi-positions) allows to turn on or off the device.